New Technique to Study Biomass Pyrolysis

  • ChemPubSoc Europe Logo
  • Author: Hilary Gallagher
  • Published Date: 13 March 2014
  • Source / Publisher: ChemSusChem/Wiley-VCH
  • Copyright: Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim
thumbnail image: New Technique to Study Biomass Pyrolysis

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Lignocellulosic biomass (dry plant matter) is the most abundant raw material for the production of biofuels. Many experts hope that a large proportion of transportation fuels can be replaced with biofuels. Thermochemical technologies for biomass conversion, such as fast pyrolysis, can produce both chemical products in high scale and liquid transportation fuels. Before these technologies can become economically viable, however, they must first be optimized through detailed modelling of the kinetics of pyrolysis.
A pyrolysis reaction is complicated, occurring in three phases: solid virgin biopolymers, gas-phase pyrolysis vapors, and a short-lived liquid intermediate. Pyrolysis in an industrial reactor is even more complicated, the three phases existing in a multi-scale system that involves atomic-scale biopolymer/melt chemistry, particle heating and reaction, and reactor conversion. In addition, the small size of wood fibres (1–2 mm) and the fast time-scale of the reaction (1–5 s) make it difficult to obtain a detailed model of pyrolysis.


Paul Dauenhauer, University of Massechusetts Amherst, USA, and co-workers have developed a new technique for determining the kinetics of pyrolysis: spatiotemporally resolved diffuse reflectance in situ spectroscopy (STR-DRiSP). The team demonstrated how the technique can characterize the composition of particles undergoing pyrolysis in both space and time. Visible light is applied to the external surface of the wood particle and diffusely reflected light is captured by using a high-speed monochrome camera. The distinct differences in absorption between lignin (high absorptive), carbohydrates (highly reflective), and char allows for characterization of the reacting wood fibers. The speed of the camera (1000 Hz) and its ability to focus on a 2D surface allows for compositional characterization in both space and time.

This new technique should help researchers understand and commercialize biomass pyrolysis.


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